TWI550453B - Touch sensor electrodes, touch panels and display devices - Google Patents

Description

Touch sensor electrode, touch panel and display device

The technology of the present invention relates to an electrode for a touch sensor including a plurality of electrodes arranged in one direction, a touch panel including an electrode for a touch sensor, and a display device.

The touch sensor provided in the display device includes a driving electrode and a sensing electrode as an example of an electrode for a touch sensor, and detects a contact of the finger or the like with respect to the operation surface as a change in electrostatic capacitance between the driving electrode and the sensing electrode. . The image formed by the display panel is output to the operation surface through the drive electrodes and the sensing electrodes. For this reason, the drive electrode and the sense electrode are, for example, a set of a plurality of electrode lines arranged at intervals with each other (for example, refer to Patent Document 1).

Prior technical literature Patent literature

Patent Document 1 Japanese Patent Laid-Open Publication No. 2012-79238

However, the electrostatic capacitance between the driving electrode and the sensing electrode is measured by a peripheral circuit connected to the electrode for the touch sensor. At this time, if the initial value of the electrostatic capacitance between the electrodes is too large, the operation surface and the finger Small capacitance changes caused by head contact are treated as measurement errors in the peripheral circuitry. Conversely, if the initial value of the electrostatic capacitance between the electrodes is too small, the noise in the peripheral circuit is treated as contact between the operation surface and the finger. Therefore, the initial value of the electrostatic capacitance between the electrodes must be a value suitable for the amount of change in capacitance caused by the contact. Such a demand is usually satisfied by forming a plurality of electrodes into mutually equal shapes and sizes, and arranging them at regular intervals.

On the other hand, the portion selected by the finger on the operation surface is defined within the output range of the image in the operation surface. At this time, if the area in which the driving electrodes are arranged or the area in which the sensing electrodes are arranged is much smaller than the output range of the image, a portion which is not selected by the finger is included in the output image. Conversely, if the area in which the driving electrodes are arranged or the area in which the sensing electrodes are arranged is much larger than the output range of the image, the measurement of the electrostatic capacitance between the electrodes is ineffectively repeated. Therefore, the size of the area in which the electrodes are arranged must be the same as the output range of the image. Such a requirement is usually satisfied by matching the size of the area in which the electrodes are arranged to the size of the display panel.

In other words, the size of the unit area required for arranging one electrode, such as the shape, size, and arrangement of the electrodes, is determined in accordance with specifications for improving the detection accuracy of the electrostatic capacitance. On the other hand, the size of the area in which the driving electrodes are arranged or the size of the area in which the sensing electrodes are arranged is determined in accordance with the size of other devices than the touch sensor. Thus, the size of the device other than the electrode for the touch sensor is usually an integer multiple of the above-described unit area of the electrode. Therefore, if the area in which the driving electrodes are arranged or the area in which the sensing electrodes are arranged is much smaller than the output range of the image, Then, the end of the output image becomes unnecessary to include the electrode portion that is originally required for detecting the contact. Conversely, if the area in which the driving electrodes are arranged or the area in which the sensing electrodes are arranged is much larger than the output range of the image, in the end portion of the area where the electrodes are arranged, the electrode portion which is not required and is not used is included. As the object area of the sensing.

As a result, since the size of the area required for arranging one electrode is predetermined, if the driving electrode or the sensing electrode is arranged to cover the entire output image, a part of the electrode will be out of the output image. Therefore, if an unnecessary electrode portion is omitted outside the output image in order to suppress the touch sensor including an unnecessary electrode portion, the initial value of the electrostatic capacitance between the electrodes is caused at the end of the electrode array region. The department became lower than in other parts.

Further, the problem that the electrostatic capacitance of the end portion of the region in which the electrodes are arranged is lower than the electrostatic capacitance of the other portions is not limited to the configuration in which the electrode portion that is not used is omitted, and the end portion of the region where the electrodes are arranged and the direction opposite thereto The relative positional shift of the electrodes occurs.

An object of the present invention is to provide an electrode for a touch sensor, a touch panel, and a display device that suppress a decrease in electrostatic capacitance at an end portion of a region where electrodes are arranged.

In one aspect of the electrode for a touch sensor of the present invention, a plurality of strip electrodes are arranged at regular intervals along a direction of arrangement in one direction, and each of the strip electrodes is disposed with a space therebetween. a plurality of sets of electrode lines, the total area of the plurality of electrode lines of each of the strip electrodes being uniform among a plurality of the strip electrodes The plurality of strip electrodes include: an end strip electrode located at least one end portion in the arrangement direction; and a strip electrode other than the end strip electrode, wherein each of the strip electrodes is The ratio of the total area of the electrode lines to the area of the strip electrodes is defined as an area ratio, and the area ratio in the end strip electrodes is different from the area ratio in the other strip electrodes.

In one aspect of the touch panel of the present invention, the electrode for the touch sensor and the cover layer covering the electrode for the touch sensor are provided, and the electrode for the touch sensor has a transparent medium. An electric body substrate; a plurality of first strip electrodes arranged in a first direction along a gap in a surface of the transparent dielectric substrate; and a plurality of second strip electrodes in the transparent dielectric The back surface of the body substrate is arranged along the second direction with a gap therebetween, and at least one of the first strip electrode and the second strip electrode is the strip electrode, and further includes a peripheral circuit for measuring the first strip The electrostatic capacitance between the electrode and the aforementioned second strip electrode.

An aspect of the display device of the present invention includes: a display panel for displaying information; a driving circuit for driving the display panel; and the touch panel for transmitting the information displayed by the display panel.

According to an aspect of the technology of the present invention, the end strip electrodes at least one end portion in the arrangement direction are equal to the other strip electrodes in terms of the total area of the electrode lines of each strip electrode. Further, the area ratio of the total area of the electrode lines to the area of the strip electrodes is different from that of the other strip electrodes. Therefore, in the end strip electrode, the strip The area of the electrode itself is different from that of the other strip electrodes, and on the other hand, the electrostatic capacitance can be suppressed to be smaller than the electrostatic capacitance of the other strip electrodes.

D1‧‧‧Arrangement direction, first alignment direction

D2‧‧‧Second alignment direction

WPM‧‧‧Intermediate electrode width

WPE‧‧‧End electrode width

W1L‧‧‧Drive electrode line width

W1W‧‧‧ drive electrode line width

W1N‧‧‧End drive electrode line width

WSM‧‧‧Intermediate electrode width

WSE‧‧‧End electrode width

W3L‧‧‧ Sense electrode line width

W3W‧‧‧ Sense electrode line width

W3N‧‧‧End sensing electrode line width

Z1‧‧‧First voltage region

Z2‧‧‧second voltage region

Z3‧‧‧ third voltage region

10‧‧‧ display panel

10S‧‧‧ display surface

11‧‧‧Lower polarizer

12‧‧‧Film Optoelectronic Substrate

13‧‧‧TFT layer

14‧‧‧Liquid layer

15‧‧‧Color filter layer

16‧‧‧Color filter substrate

17‧‧‧Upper polarizer

20‧‧‧Touch panel

20S‧‧‧Operation surface

21‧‧‧Electrode for touch sensor

22‧‧‧ Coverage

23‧‧‧Transparent layer

31DP‧‧‧Strip electrode, drive electrode

31L‧‧‧electrode wire

31DE‧‧‧End strip electrode

31DM‧‧‧Other strip electrodes

31‧‧‧Transparent substrate

31S‧‧‧ drive surface

31L‧‧‧ drive electrode line

31T‧‧‧ pads

31DP1‧‧‧first drive electrode

31DPn‧‧‧nth drive electrode

31DE‧‧‧End Drive Electrode

31DM‧‧‧Intermediate drive electrode

31DL‧‧‧virtual pattern

31C‧‧‧Gap section

32‧‧‧Transparent layer

33‧‧‧Transparent dielectric substrate

33S‧‧‧ sensing surface

33L‧‧‧Sensing electrode line

33T‧‧‧ pads

33SP‧‧‧Sensor electrode

33SP1‧‧‧first sensing electrode

33SPn‧‧‧nth sensing electrode

33SE‧‧‧End sensing electrode

33SM‧‧‧Intermediate sensing electrode

33DL‧‧‧virtual pattern

33C‧‧‧ gap

34‧‧‧Selection circuit

35‧‧‧Detection circuit

35‧‧‧Detection circuit

35a‧‧‧Signal Acquisition Department

35b‧‧‧Signal Processing Department

35L‧‧‧second drive electrode line

36‧‧‧Control Department

Fig. 1 is a plan view showing a plan view of a display device in the first embodiment, in which a part of mutually overlapping constituent elements are superimposed.

Fig. 2 is a cross-sectional view showing a cross-sectional structure of the display device of Fig. 1.

Fig. 3 is a block diagram showing an electrical configuration of a touch panel of the display device of Fig. 1.

Fig. 4 is a plan view showing the arrangement of drive electrodes of the display device of Fig. 1.

Fig. 5 is a plan view showing an arrangement relationship between a driving electrode and a sensing electrode of the display device of Fig. 1.

6 is a numerical calculation result of a voltage distribution obtained by using a finite element method between a sensing electrode and a driving electrode when the interval between the sensing electrodes is 600 μm in the electrode for the touch sensor of the display device of FIG. 1 . .

Fig. 7 is a view showing numerical calculation results of a voltage distribution obtained by a finite element method between a sensing electrode and a driving electrode when the interval between the sensing electrodes is 300 μm in the electrode for the touch sensor of the display device of Fig. 1; .

Fig. 8 is a plan view showing a planar configuration of a driving electrode in a modification.

Fig. 9 is a plan view showing a planar configuration of a driving electrode in a modification.

Fig. 10 is a plan view showing the arrangement relationship of the drive electrodes and the sensing electrodes in the second embodiment.

Fig. 11 is a plan view showing the arrangement relationship of the driving electrode and the sensing electrode in the modification.

Fig. 12 is a plan view showing the arrangement relationship of the driving electrode and the sensing electrode in the modification.

Fig. 13 is a cross-sectional view showing a cross-sectional structure of a display device in a modification.

Fig. 14 is a cross-sectional view showing a cross-sectional structure of a display device in a modification.

[Formation for carrying out the invention] [First Embodiment]

An embodiment in which the electrode for a touch sensor, the touch panel, and the display device according to the present invention are embodied will be described with reference to FIGS. 1 to 8. First, the configuration of the display device will be described with reference to Fig. 1 .

also. In the first drawing, the drive electrode and the sensing electrode are exaggerated for convenience in explaining the configuration of the drive electrode formed on the driving surface and the sensing electrode formed on the sensing surface.

[display device]

As shown in FIG. 1, the display device is bonded to a liquid crystal panel or an organic EL panel driven by a driving circuit by a transparent adhesive layer. The display panel 10 and the like, and the laminated body formed by the touch panel 20. On the surface of the display panel 10, a display surface 10S formed in a rectangular shape is divided, and an image based on image data from the outside is displayed on the display surface 10S.

The touch panel 20 is a laminated body in which the touch sensor electrode 21 and the cover layer 22 are bonded to each other by the transparent adhesive layer 23 . The cover layer 22 is formed of a glass substrate or a resin film, and the side surface of the cover layer 22 opposite to the transparent adhesive layer 23 functions as the operation surface 20S of the touch panel 20. The transparent adhesive layer 23 has light transmittance for transmitting an image displayed on the display surface 10S, and the transparent adhesive layer 23 is, for example, a polyether adhesive or an acrylic adhesive.

Further, when the touch panel 20 is manufactured, the touch sensor electrode 21 and the cover layer 22 may be bonded to each other by the transparent adhesive layer 23. As a different example, the following manufacturing method may be employed. In other words, a film layer made of a conductive metal such as copper is formed directly on the cover layer 22 such as a resin film or a base layer, and a resist layer having a shape of an electrode pattern for a touch sensor is formed thereon. Next, the film layer is processed into an electrode for a touch sensor extending in the X direction by a wet etching method using ferric chloride or the like to obtain a first film. Further, similarly to the electrode for the touch sensor extending in the X direction, the film layer is processed into an electrode for a touch sensor extending in the Y direction to obtain a second film. Then, the first film and the second film are bonded together by the transparent adhesive layer 23.

The transparent substrate 31 which is an example of the first substrate, which is a component of the touch sensor electrode 21, overlaps with the entire display surface 10S formed on the display panel 10, and transmits an image formed on the display surface 10S. The transparent substrate 31 is, for example, made of transparent glass or a transparent tree It is composed of a substrate such as a lipid film. The transparent substrate 31 may have a single layer structure composed of one substrate, or may have a multilayer structure in which two or more substrates are stacked.

The surface of the transparent substrate 31 opposite to the display panel 10 is set as the driving surface 31S, and on the driving surface 31S of the transparent substrate 31, the plurality of driving electrode lines 31L of one example of the electrode lines are first along one direction. Arranged in the direction of the column D1. Each of the plurality of driving electrode lines 31L is formed in a polygonal line shape extending in the second arrangement direction D2 orthogonal to the first arrangement direction D1.

The plurality of driving electrode lines 31L are each divided into a group of nine from the driving electrode line 31L located at the end of the first arrangement direction D1. A set of nine driving electrode wires 31L are connected to one pad 31T. The nine drive electrode lines 31L connected to one pad 31T and arranged at intervals along the first arrangement direction D1 constitute one drive electrode 31DP of an example of the first strip electrode.

Each of the plurality of driving electrode lines 31L is a metal oxide film made of copper or aluminum, a metal oxide film made of zinc oxide or the like, or a composite oxide film made of indium tin oxide or indium gallium zinc oxide. Indium tin oxide or indium gallium zinc is formed of a metal oxide containing indium, tin, gallium, zinc, or the like. Further, each of the plurality of driving electrode wires 31L may be a silver nanowire, a conductive polymer film, or a conductive film. A graphene film etc. are mentioned as a conductive film. The plurality of drive electrodes 31DP each including the nine drive electrode lines 31L are individually connected to the selection circuit 34, and are selected by the drive voltage applied by the selection circuit 34.

The plurality of driving electrode lines 31L and the plurality of pads 31T can be simultaneously formed by etching a film formed on the driving surface 31S via a mask. Alternatively, the plurality of driving electrode lines 31L and the plurality of pads 31T may be formed of mutually different materials by using other processes. Further, the plurality of driving electrode lines 31L and the plurality of pads 31T may be formed on another substrate different from the transparent substrate 31 by attaching a plurality of driving electrode lines 31L and a plurality of pads 31T from other substrates. The transparent substrate 31 is formed.

The driving surface 31S, the plurality of driving electrode lines 31L, and the plurality of pads 31T are bonded to the transparent dielectric substrate 33 of one example of the second substrate by a transparent adhesive layer 32. The transparent adhesive layer 32 has light transmittance for transmitting an image displayed on the display surface 10S. The transparent adhesive layer 32 is followed by a driving surface 31S, a plurality of driving electrode lines 31L, a plurality of pads 31T, and a transparent dielectric substrate 33. The transparent adhesive layer 32 is, for example, a polyether adhesive or an acrylic adhesive. The transparent adhesive layer 32 and the transparent dielectric substrate 33 are constituent elements of the transparent dielectric substrate, and a plurality of driving electrode lines 31L and a plurality of pads 31T are formed on the back surface of the transparent dielectric substrate.

The transparent dielectric substrate 33 is made of, for example, a transparent resin film such as polyethylene terephthalate or a base material such as a transparent glass substrate. The transparent dielectric substrate 33 may have a single layer structure composed of one substrate, or may have a multilayer structure in which two or more substrates are stacked. The transparent dielectric substrate 33 has a light transmittance for transmitting an image displayed on the display surface 10S and a specific dielectric ratio suitable for detecting an electrostatic capacitance between the electrodes.

The surface of the transparent dielectric substrate 33 opposite to the transparent adhesive layer 32 is set as the sensing surface 33S, and the sensing surface 33S of the transparent dielectric substrate 33 is a plurality of sensing electrodes of one example of the electrode lines. The lines 33L are arranged along the second arrangement direction D2. Each of the plurality of sensing electrode lines 33L is formed in a polygonal line shape extending along the first arrangement direction D1.

The plurality of sensing electrode lines 33L are each divided into a group of nine from the sensing electrode line 33L located at the end of the second array direction D2. A set of nine sensing electrode lines 33L are connected to one pad 33T. The nine sensing electrode lines 33L connected to one pad 33T and spaced apart along the second arrangement direction D2 constitute one sensing electrode 33SP of one example of the opposing strip electrodes of the second strip electrode.

Similarly to the drive electrode line 31L, the plurality of sensing electrode lines 33L each use a metal film made of copper or aluminum, a metal oxide film made of zinc oxide or the like, or indium tin oxide or indium gallium zinc oxide. A composite oxide film composed of the like. Indium tin oxide or indium gallium zinc is formed of a metal oxide containing indium, tin, gallium, and zinc. Further, a plurality of conductive electrodes such as a silver nanowire, a conductive polymer film, and a graphene film may be used for each of the plurality of sensing electrode lines 33L. A graphene film etc. are mentioned as a conductive film. A plurality of sensing electrodes 33SP each including nine sensing electrode lines 33L are individually connected to the detecting circuit 35, and the voltage of each sensing electrode 33SP is detected by the detecting circuit 35.

The plurality of sensing electrode lines 33L and the plurality of pads 33T can be simultaneously formed by etching a film formed on the sensing surface 33S via a mask. Alternatively, the plurality of sensing electrode lines 33L and the plurality of pads 33T may be made of different materials by using other processes. Material formation. Further, the plurality of sensing electrode lines 33L and the plurality of pads 33T may be formed on other substrates different from the transparent dielectric substrate 33 by using a plurality of sensing electrode lines 33L and a plurality of pads 33T from the other The substrate is formed by being attached to the transparent dielectric substrate 33.

The sensing surface 33S, the plurality of sensing electrode lines 33L, and the plurality of pads 33T are bonded to the cover layer 22 by the transparent adhesive layer 23 described above.

[Profile structure of display device]

The cross-sectional structure of the display device will be described with reference to Fig. 2 . Further, Fig. 2 shows an example in which a liquid crystal panel is used as a display panel.

In the touch panel 20, the transparent substrate 31, the driving electrode 31DP, the transparent adhesive layer 32, the transparent dielectric substrate 33, the sensing electrode 33SP, and the transparent adhesive layer 23 are sequentially disposed from the components close to the display panel 10. And a cover layer 22. The transparent adhesive layer 32 covers the periphery of each of the electrode lines 31L constituting the drive electrodes 31DP, and buryes between the adjacent electrode lines 31L and is located between the drive electrodes 31DP and the transparent dielectric substrate 33. Further, the transparent adhesive layer 23 covers the periphery of each of the electrode lines 33L constituting the sensing electrodes 33SP, buryes between the adjacent electrode lines 33L, and is located between the sensing electrodes 33SP and the cap layer 22.

In the display panel 10, a plurality of constituent elements of the display panel 10 are sequentially arranged as follows from the constituent elements far from the touch panel 20. That is, the lower polarizing plate 11, the thin film transistor (hereinafter referred to as TFT) substrate 12, the TFT layer 13, the liquid crystal layer 14, the color filter layer 15, and the color filter are sequentially placed from the constituent elements away from the touch panel 20. The light sheet substrate 16 and the upper polarizing plate 17. Wherein, in the TFT layer 13, The pixel electrodes constituting the sub-pixels are placed in a matrix. Then, in the color filter layer 15, the black matrix divides a plurality of regions having a rectangular shape facing each sub-pixel, and places white light into any of red, green, and blue in each region of the black matrix division. The color layer of light.

[Electrical composition of touch panel]

The electrical configuration of the touch panel 20 will be described with reference to FIG. In the following, an electrical configuration of the mutual capacitive touch panel 20 will be described as an example of the capacitive touch panel 20 .

As shown in FIG. 3, the touch panel 20 includes a selection circuit 34, a detection circuit 35, and a control unit 36. The selection circuit 34 can be connected to a plurality of drive electrodes 31DP, the detection circuit 35 can be connected to a plurality of sensing electrodes 33SP, and the control portion 36 is connected to the selection circuit 34 and the detection circuit 35.

The control unit 36 generates and outputs a start timing signal for causing the selection circuit 34 to start generating a driving signal for each of the driving electrodes 31DP. The control unit 36 generates and outputs a scan timing signal for causing the selection circuit 34 to sequentially scan the object to which the drive signal is supplied from the first drive electrode 31DP1 toward the nth drive electrode 31DPn.

The control unit 36 generates and outputs a start timing signal for causing the detection circuit 35 to start detecting the current flowing at each of the sensing electrodes 33SP. The control unit 36 generates and outputs a scan timing signal for causing the detection circuit 35 to sequentially scan the detected object from the first sensing electrode 33SP1 toward the nth sensing electrode 33SPn.

The selection circuit 34 starts to generate the driving signal according to the start timing signal output from the control unit 36, and scans the output of the driving signal from the first driving electrode 31DP1 toward the nth driving electrode 31DPn according to the scanning timing signal output from the control unit 36. .

The detection circuit 35 includes a signal acquisition unit 35a and a signal processing unit 35b. The signal acquisition unit 35a starts to acquire the current signal belonging to the analog signal generated by each of the sensing electrodes 33SP based on the start timing signal output from the control unit 36. Then, the signal acquisition unit 35a scans the source of the current signal from the first sensing electrode 33SP1 toward the nth sensing electrode 33SPn based on the scanning timing signal output from the control unit 36.

The signal processing unit 35b processes the current signals obtained by the signal acquisition unit 35a, generates a voltage signal of a digital value, and outputs the generated voltage signal to the control unit 36. In this manner, the selection circuit 34 and the detection circuit 35 measure the change in electrostatic capacitance between the drive electrode 31DP and the sense electrode 33SP by generating a voltage signal from a current signal that changes with a change in electrostatic capacitance. The selection circuit 34 and the detection circuit 35 are examples of peripheral circuits for driving the electrodes for the touch panel.

The control unit 36 detects the position touched by the user on the touch panel 20 based on the voltage signal output from the signal processing unit 35b.

Further, the touch panel 20 is not limited to the above-described mutual capacitive touch panel 20, and may be a self-capacitive capacitive touch panel.

[Electrode 31DP, 33SP]

Next, the configuration of the drive electrode 31DP and the sense electrode 33SP will be described with reference to FIGS. 4 and 5. Fig. 4 is a plan view showing the planar configuration of the driving electrode 31DP, and Fig. 5 is a sub-product. A plan view of the drive electrode 31DP and the sense electrode 33SP is viewed in the layer drive electrode 31DP and the sense electrode 33SP direction. 4 and 5, the line width of the drive electrode line 31L and the line width of the sense electrode line 33L are exaggerated for convenience in explaining the arrangement of the drive electrode line 31L and the arrangement of the sense electrode line 33L. .

[Drive Electrode 31DP]

As shown in FIG. 4, one drive electrode 31DP includes nine drive line wires 31L formed in a zigzag line extending along the second arrangement direction D2, and is a strip electrode extending in the second arrangement direction D2. That is, the respective areas of the plurality of driving electrodes 31DP are included in the driving surface 31S, and include a gap between the nine driving electrode lines 31L and the driving electrode lines 31L adjacent to each other, and each of the plurality of driving electrodes 31DP is in a mutual equal. The plurality of drive electrodes 31DP are each arranged in the first arrangement direction D1.

Among the plurality of drive electrodes 31DP, the drive electrodes 31DP disposed at both end portions of the region where the drive electrodes 31DP are arranged are set as the end drive electrodes 31DE. Among the plurality of drive electrodes 31DP, the drive electrodes 31DP other than the end drive electrodes 31DE are set as the intermediate drive electrodes 31DM.

In the first arrangement direction D1, the respective positions of the plurality of intermediate drive electrodes 31DM are positions overlapping the display surface 10S. The plurality of intermediate drive electrodes 31DM are set to have an intermediate electrode width WPM along the length in the first arrangement direction D1, and the intermediate electrode width WPM is set to, for example, 5.4 mm.

In the first arrangement direction D1, the respective positions of the two end drive electrodes 31DE are across the inner side of the display surface 10S and the outer side of the display surface 10S. The length of each of the end drive electrodes 31DE in the first arrangement direction D1 is set to the end electrode width WPE, and the end electrode width WPE is smaller than the intermediate electrode width WPM, for example, set to 4.8 mm.

Since the end electrode width WPE is smaller than the intermediate electrode width WPM, all of the drive electrodes 31DP are arranged in the region where the drive electrodes 31DP having the end electrode width WPE and the intermediate electrode width WPM are arranged, compared to the configuration having the intermediate electrode width WPM. The length along the first arrangement direction D1 becomes shorter. Therefore, in the end portion of the region where the driving electrodes 31DP are arranged, the portion including the portion other than the sensing target region is suppressed. Further, the sensed object region refers to a portion of the region in which the drive electrodes 31DP are arranged to overlap with the display surface 10S.

In the plurality of drive electrode lines 31L, the length along the first arrangement direction D1 is set to the drive electrode line width W1L, and the drive electrode line width W1L is set to, for example, 5 μm.

The plurality of driving electrode lines 31L in the intermediate driving electrode 31DM and the driving electrode lines 31L adjacent to each other are set to have a width W1W between the driving electrodes, and the width W1W between the driving electrodes is set to, for example, 600 μm.

The drive electrode line 31L in the end drive electrode 31DE has the same width as the drive electrode line 31L in the intermediate drive electrode 31DM. That is, in each of the plurality of driving electrodes 31DP, the total area occupied by the nine driving electrode lines 31L of each of the driving electrodes 31DP is uniform and equal to each other in the driving surface 31S.

Further, the width of the drive electrode line 31L in the end drive electrode 31DE may be larger than the width of the drive electrode line 31L in the intermediate drive electrode 31DM.

The plurality of driving electrode lines 31L in the end driving electrodes 31DE and the driving electrode lines 31L adjacent to each other are set to have a width W1W between the driving electrodes and a width W1N between the end driving electrodes. The end drive electrode line width W1N is set to, for example, 300 μm which is 1/2 of the drive electrode line width W1W. The end drive electrode 31DE includes a portion having the width W1W between the drive electrode lines as an example of the first electrode portion, and includes a portion having the width W1N between the end drive electrodes as an example of the second electrode portion.

Since the width W1N between the end driving electrode lines is smaller than the width W1W between the driving electrode lines, the entire gap between the driving electrode lines 31L has a width W1W between the driving electrode lines, and the driving electrode line 31L occupies the end driving electrode. The area per unit area in the 31DE is larger than the area per unit area of the intermediate driving electrode 31DM than the driving electrode line 31L. In other words, the ratio of the total area of the drive electrode lines 31L to the area of the drive electrodes 31DP is larger than the ratio of the ratio of the end drive electrodes 31DE to the intermediate drive electrodes 31DM.

Therefore, although the end electrode width WPE is smaller than the intermediate electrode width WPM, the electrostatic capacitance of the end drive electrode 31DE is suppressed to be smaller than the electrostatic capacitance of the intermediate drive electrode 31DM. As a result, it is suppressed that the detection accuracy of the electrostatic capacitance at the end drive electrode 31DE becomes lower than the detection accuracy of the electrostatic capacitance of the intermediate drive electrode 31DM. At this time, the unit area in the driving electrode 31DP is in the middle. The drive electrode 31DM includes two or more drive electrode lines 31L in size.

Further, the two drive electrode lines 31L which are separated from each other only by the end drive electrode line width W1N are preferably located at the end of the region where the drive electrodes 31DP are arranged. The drive electrode lines 31L arranged in the width W1N between the end drive electrodes are densely arranged than the drive electrode lines 31L arranged in the width W1W between the drive electrodes. In this regard, when the drive electrode lines 31L arranged in the width W1N between the end drive electrodes are arranged at the end portions of the regions where the drive electrodes 31DP are arranged, the densely arranged drive electrode lines 31L become difficult to be Identification.

Further, the end drive electrode line width W1N is preferably twice or more the thickness of the transparent dielectric substrate 33. When the width W1N between the end drive electrode lines is twice or more the thickness of the transparent dielectric substrate 33, the density variation in the plurality of drive electrode lines 31L becomes difficult to be recognized. Further, as the width W1N between the end drive electrode lines becomes smaller, the electrostatic capacitance between the drive electrode lines 31L becomes larger. In this regard, when the end drive electrode line width W1N is twice or more the thickness of the transparent dielectric substrate 33, the drive electrode line 31L due to the electrostatic capacitance between the drive electrode lines 31L can be suppressed. The variation of the electrostatic capacitance between the electrode lines 33L is sensed.

[Sensor Electrode 33SP]

As shown in FIG. 5, one sensing electrode 33SP includes nine strip-shaped sensing electrode lines 33L that are formed in a line shape extending along the first array direction D1, and are opposite strips extending along the first array direction D1. electrode. That is, the respective areas of the plurality of sensing electrodes 33SP are on the sensing surface 33S. The gap between the nine sensing electrode lines 33L and the sensing electrode lines 33L adjacent to each other is included, and each of the plurality of sensing electrodes 33SP is equal to each other. Each of the plurality of sensing electrodes 33SP is arranged along the second arrangement direction D2, and is disposed at a position intersecting each of the plurality of drive electrodes 31DP as viewed in plan view.

Among the plurality of sensing electrodes 33SP, the sensing electrodes 33SP disposed at both end portions of the region where the sensing electrodes 33SP are arranged are set as the end sensing electrodes 33SE. Among the plurality of sensing electrodes 33SP, the sensing electrodes 33SP other than the end sensing electrodes 33SE are set as the intermediate sensing electrodes 33SM.

In the second arrangement direction D2, the respective positions of the plurality of intermediate sensing electrodes 33SM are positions overlapping the display surface 10S. The length of the plurality of intermediate sensing electrodes 33SM along the second array direction D2 is set to the intermediate electrode width WSM, and the intermediate electrode width WSM is set to, for example, 5.4 mm in the same manner as the intermediate electrode width WPM.

In the second arrangement direction D2, the respective positions of the two end sensing electrodes 33SE are across the inner side of the display surface 10S and the outer side of the display surface 10S. The length of the two end sensing electrodes 33SE along the second arrangement direction D2 is set to the end electrode width WSE, and the end electrode width WSE is smaller than the intermediate electrode width WSM, similarly to the end electrode width WPE. For example, it is set to 4.8 mm.

Since the end electrode width WSE is smaller than the intermediate electrode width WSM, the intermediate electrode width WSM is formed in comparison with all of the sensing electrodes 33SP, and is arranged in the sensing electrode 33SP having the end electrode width WSE and the intermediate electrode width WSM. Area, along the first The length of the second arrangement direction D2 becomes shorter. Therefore, in the end portion of the region where the sensing electrodes 33SP are arranged, the portion including the portion other than the sensing target region is suppressed.

The length of each of the plurality of sensing electrode lines 33L along the second arrangement direction D2 is set to the sensing electrode line width W3L, and the sensing electrode line width W3L is set to, for example, 5 μm.

The sensing electrode line 33L in the intermediate sensing electrode 33SM, the interval between the sensing electrode lines 33L adjacent to each other is set to the sensing electrode line width W3W, and the sensing electrode line width W3W is set to, for example, 600 μm.

The sensing electrode line 33L in the end sensing electrode 33SE has the same width as the sensing electrode line 33L in the intermediate sensing electrode 33SM. That is, in the plurality of sensing electrodes 33SP, the total area occupied by the nine sensing electrode lines 33L of each of the sensing electrodes 33SP is uniform and equal to each other in the sensing surface 33S.

Also, the width of the sensing electrode line 33L in the end sensing electrode 33SE may be larger than the width of the sensing electrode line 33L in the intermediate sensing electrode 33SM.

The plurality of sensing electrode lines 33L in the end sensing electrodes 33SE are spaced apart from each other by the sensing electrode line width W3W and the end sensing electrode line width W3N. The end sensing electrode line width W3N is set, for example, to 300 μm which is 1/2 of the width W3W between the sensing electrode lines. The end sensing electrode 33SE includes a portion having the width W3W between the sensing electrode lines as an example of the first electrode portion, and includes a portion having the width W3N between the end sensing electrodes as an example of the second electrode portion.

Since the end sensing electrode line width W3N is smaller than the sensing electrode line width W3W, the entire gap between the sensing electrode lines 33L has a sensing electrode line width W3W, and the sensing electrode line 33L The area per unit area in the end sensing electrode 33SE is larger than the area of the unit area in the intermediate sensing electrode 33SM than the sensing electrode line 33L. In other words, the ratio of the total area of the sensing electrode lines 33L to the area of the sensing electrodes 33SP is larger at the ratio of the ratio of the end sensing electrodes 33SE to the ratio of the intermediate sensing electrodes 33SM.

Therefore, although the end electrode width WSE is smaller than the intermediate electrode width WSM, the case where the electrostatic capacitance of the end sensing electrode 33SE becomes smaller than the electrostatic capacitance of the intermediate sensing electrode 33SM is suppressed. As a result, the case where the detection accuracy of the electrostatic capacitance of the end sensing electrode 33SE becomes lower than the detection accuracy of the electrostatic capacitance of the intermediate sensing electrode 33SM is suppressed. At this time, the unit area in the sensing electrode 33SP refers to a size including two or more sensing electrode lines 33L in the intermediate sensing electrode 33SM.

Further, the two sensing electrode lines 33L located at positions separated from each other by the end portion sensing electrode line width W3N are preferably end portions of the region where the sensing electrodes 33SP are arranged. The sensing electrode lines 33L arranged across the end sensing electrode line width W3N are densely arranged than the sensing electrode lines 33L arranged across the sensing electrode line width W3W. In this regard, if the sensing electrode lines 33L arranged across the end sensing electrode line width W3N are disposed at the ends of the regions where the sensing electrodes 33SP are arranged, the densely arranged sensing electrode lines The 33L becomes difficult to recognize.

Further, the end sensing electrode line width W3N is preferably twice or more the thickness of the transparent dielectric substrate 33. If the end sensing electrode line When the width W3N is twice or more the thickness of the transparent dielectric substrate 33, the variation in density in the plurality of sensing electrode lines 33L becomes difficult to be recognized. Further, as the width W3N between the end sensing electrode lines becomes smaller, the electrostatic capacitance between the sensing electrode lines 33L becomes larger. In this regard, if the end sensing electrode line width W3N is more than twice the thickness of the transparent dielectric substrate 33, the driving electrode line caused by the electrostatic capacitance between the sensing electrode lines 33L can be suppressed. Variation in electrostatic capacitance between 31L and sense electrode line 33L.

[Results of numerical calculation of electrostatic capacitance]

Next, the electrostatic capacitance between the drive electrode 31DP and the sense electrode 33SP obtained by numerical calculation will be described below.

The numerical calculation of the electrostatic capacitance between the drive electrode 31DP and the sense electrode 33SP first sets the thickness, the specific dielectric constant, and the sheet resistance of each constituent member to the following values. Further, an atmosphere layer having a thickness of 1 mm and a specific dielectric constant of 1.00 was set on the upper side of the cover layer 22 and on the lower side of the transparent substrate 31. Then, for the target region having a rectangular shape of 5 mm along the first arrangement direction D1 and 5 mm along the second arrangement direction D2, the numerical calculation using the finite element method to solve the Laplace equation is used to calculate the drive electrode 31DP and the sensing. The electrostatic capacitance between the electrodes 33SP.

‧ Cover layer 22 thickness: 700μm / specific dielectric ratio: 6.00

‧ Transparent adhesive layer 23 thickness: 75μm / specific dielectric ratio: 2.60

‧All sensing electrode lines 33L Thickness: 2μm/piece resistance: 0.168Ω/□

‧ Transparent dielectric substrate 33 thickness: 100μm / specific dielectric ratio: 3.25

‧ Transparent adhesive layer 32 thickness: 50μm / specific dielectric ratio: 2.60

‧All drive electrode lines 31L Thickness: 2μm/piece resistance: 0.168Ω/□

‧ Transparent substrate 31 thickness: 100μm / specific dielectric ratio: 3.25

‧Drive electrode line width WIW 600μm

‧ End drive electrode line width WIN 300μm

‧ Sense electrode line width W3W 600μm

‧End sensing electrode line width W3N 300μm

The numerical calculation result under the above conditions is between the case where the target region is the intermediate sensing electrode 33SM and the case where the target region is the end sensing electrode 33SE, between the driving electrode 31DP and the sensing electrode 33SP The electrostatic capacitance is 1.01pF. On the other hand, for example, in the case where the number of sensing electrode lines 33L constituting the intermediate sensing electrode 33SM is eight, the electrostatic capacitance between the intermediate sensing electrode 33SM and the intermediate driving electrode 31DM is lowered to 0.79 pF.

Here, the configuration in which the end electrode width WPE is made smaller than the intermediate electrode width WPM is a configuration in which the number of the drive electrode lines 31L included in the end drive electrode 31DE is reduced. In addition, the configuration in which the end electrode width WSE is smaller than the intermediate electrode width WSM is a configuration in which the number of the sensing electrode lines 33L included in the end portion sensing electrodes 33SE is reduced. However, only the configuration in which the number of the electrode lines 31L and 33L is small is as shown in the numerical calculation results described above, and the electrostatic capacitance in the end driving electrode 31DE and the end sensing electrode 33SE becomes larger than that in the other electrodes 31DP, 33SP. The electrostatic capacitance is low.

On the other hand, in the above-described configuration, the area occupied by the electrode lines 31L and 33L in the unit area of the electrodes 31DP and 33SP having the end electrode widths WPE and WSE is the ratio of the electrode lines 31L and 33L to the other electrodes 31DP. The other area occupied by the 33SP is large. Therefore, as shown by the above numerical calculation results, the electrodes 31DP and 33SP having the end electrode widths WPE and WSE also have the same electrostatic capacitance as the other electrodes 31DP and 33SP.

Next, the voltage distribution between the drive electrode 31DP and the sense electrode 33SP obtained by numerical calculation will be described with reference to FIGS. 6 and 7.

Further, in FIGS. 6 and 7, the voltage amplitude at the portion where the drive electrode 31DP and the sense electrode 33SP intersect in plan view is set to 1.0. Then, in the sixth and seventh figures, a region showing a voltage width of 0.8 times or more and 1.0 times or less with respect to the voltage amplitude at the intersection portion is set as the first voltage region Z1, and is displayed 0.7 times or more and less than 0.8. The area of the multiple voltage amplitude is set to the second voltage region Z2. Further, in FIGS. 6 and 7, the region in which the voltage amplitude of 0.2 times or more and less than 0.7 times is displayed with respect to the voltage amplitude at the intersection portion is set as the third voltage region Z3.

Numerical calculation of the voltage distribution between the drive electrode 31DP and the sense electrode 33SP firstly sets the thickness, specific dielectric constant, and sheet resistance of each constituent member in the same manner as the numerical calculation of the electrostatic capacitance. Further, an atmosphere layer having a thickness of 1 mm and a specific dielectric constant of 1.00 was set on the upper side of the cover layer 22 and on the lower side of the transparent substrate 31. Then, the voltage applied to the sensing electrode 33SP is changed to 0 V, which is applied to the driving electrode 31DP. The voltage is changed to 3 V to 20 V, and the voltage distribution between the drive electrode 31DP and the sense electrode 33SP is calculated using numerical calculation using the finite element method to solve the Laplace equation.

As shown in FIG. 6, the interval between the sensing electrode lines 33L adjacent to each other is the portion where the width W3W between the sensing electrode lines is the first voltage region Z1, the second voltage region Z2, and the third voltage region Z3. A gap between the sensing electrode lines 33L adjacent to each other. Therefore, if the interval between the sensing electrode lines 33L adjacent to each other is the width W3W between the sensing electrode lines, the interference between the sensing electrode lines 33L between the sensing electrode lines 33L adjacent to each other can be sufficiently ignored. the size of.

As shown in FIG. 7, the second voltage region Z2 and the third voltage region Z3 are adjacent to each other at a portion where the interval between the sensing electrode lines 33L adjacent to each other is the end sensing electrode line width W3N. The gap between the sensing electrode lines 33L. Therefore, even if the interval between the sensing electrode lines 33L adjacent to each other is the end sensing electrode line width W3N, the interference between the sensing electrode lines 33L is negligible between the sensing electrode lines 33L adjacent to each other. The extent of the size. That is, if the interval (300 μm) of the sensing electrode lines 33L adjacent to each other is at least twice or more than the interval (150 μm) between the driving electrodes 31DP and the sensing electrodes 33SP, the interference between the sensing electrode lines 33L can be The degree of neglect.

[The role of the display device]

When the display panel 10 displays an image on the display surface 10S, the image displayed on the display surface 10S is output to the surface of the cover layer 22 through the drive electrode 31DP and the sensing electrode 33SP. Among the operation surfaces belonging to the surface of the cover layer 22, the area overlapping the display surface 10S in the plan view direction is a portion selected by the finger.

At this time, among the regions in which the drive electrodes 31DP are arranged, the portion overlapping the display surface 10S is set as the sensing target region, and the drive electrodes 31DP are arranged to cover the entire sensed target region. Further, among the regions in which the sensing electrodes 33SP are arranged, the portion overlapping the display surface 10S is also set as the sensing target region, and the sensing electrodes 33SP are arranged to cover the entire sensed object region. Therefore, when the finger or the like contacts the image output range in the operation surface, the electrostatic capacitance between the drive electrode 31DP and the sense electrode 33SP changes at a portion where the finger or the like contacts. Thus, the position at which the finger is in contact with the operation surface is grasped by detecting a change in electrostatic capacitance.

Then, since the end electrode width WPE is smaller than the intermediate electrode width WPM, the length along the first array direction D1 becomes shorter in the region where the drive electrode 31DP having the end electrode width WPE and the intermediate electrode width WPM is arranged. Further, since the end electrode width WSE is smaller than the intermediate electrode width WSM, the length along the second arrangement direction D2 becomes shorter in the region where the sensing electrodes 33SP having the end electrode width WSE and the intermediate electrode width WSM are arranged. Therefore, it is suppressed that the end portion of the region where the drive electrodes 31DP are arranged and the end portion of the region where the sensing electrodes 33SP are arranged include a portion other than the sensed target region.

Further, since the end drive electrode line width W1N is smaller than the drive electrode line width W1W, the drive electrode line 31L occupies an area per unit area in the end drive electrode 31DE, and the drive electrode line 31L occupies the intermediate drive electrode 31DM. The area per unit area is large. Moreover, since the end sensing electrode line width W3N is smaller than the sensing electrode line width W3W, the sensing electrode line 33L occupies the end sensing electrode 33SE The area per unit area is larger than the area of the unit area in the intermediate sensing electrode 33SM than the sensing electrode line 33L. Therefore, the electrostatic capacitance of the end driving electrode 31DE is suppressed to be smaller than the electrostatic capacitance of the intermediate driving electrode 31DM, and the electrostatic capacitance of the end sensing electrode 33SE is suppressed to be smaller than that of the intermediate sensing electrode 33SM. The situation.

According to the first embodiment described above, the following advantages can be obtained.

(1) The configuration in which the widths of the drive electrodes 31DP in the first arrangement direction D1 are equal to each other, and the end portions of the regions where the drive electrodes 31DP are arranged include the target region to be sensed. Part of the situation.

(2) Compared with the configuration in which the widths of the sensing electrodes 33SP in the second arrangement direction D2 are equal to each other across the sensing electrodes 33SP, it is suppressed that the ends of the regions where the sensing electrodes 33SP are arranged include sensing The case of a part other than the object area.

(3) The area of the electrode line occupying the unit area in the end drive electrode 31DE is larger than the area of the unit line in the other drive electrode 31DP. Thereby, the area of the end drive electrode 31DE (the strip electrode) itself becomes smaller than the other drive electrodes 31DP (other strip electrodes), and on the other hand, the electrostatic capacitance of the end drive electrode 31DE is suppressed to become larger than that of the other drive electrodes. The 31DP has a small electrostatic capacitance.

(4) The electrode line occupies an area per unit area in the end sensing electrode 33SE, which is larger than the area of the unit line in the other sensing electrodes 33SP. Thereby, the area of the end sensing electrode 33SE (the strip electrode) itself becomes smaller than the other sensing electrodes 33SP (other strip electrodes), and On the one hand, the case where the electrostatic capacitance of the end sensing electrode 33SE becomes smaller than the electrostatic capacitance of the other sensing electrodes 33SP is suppressed.

(5) In the end driving electrode 31DE, the interval between the driving electrode lines 31L adjacent to each other is the width W1N between the end driving electrode lines, whereby the area of the electrode line constituting the unit area is made larger than the other strip electrodes (ie, the middle The drive electrode 31DM) is large. Therefore, when the area of the electrode line per unit area is increased, it is not necessary to change the size of the drive electrode line 31L and change the shape of the drive electrode line 31L.

(6) In the end sensing electrode 33SE, the interval between the sensing electrode lines 33L adjacent to each other is the width W3N between the end sensing electrode lines, whereby the area of the electrode line constituting the unit area is made larger than that of the other strip electrodes ( That is, the intermediate sensing electrode 33SM) is large. Therefore, when the area of the electrode line per unit area is increased, it is not necessary to change the size of the sensing electrode line 33L and change the shape of the sensing electrode line 33L.

(7) In the end drive electrode 31DE, the interval between the drive electrode lines 31L adjacent to each other is a portion of the drive electrode line width W1W. Therefore, the case where the end drive electrode 31DE and the intermediate drive electrode 31DM are recognized as mutually different electrodes is suppressed.

Further, as an example of the first electrode portion included in the end drive electrode 31DE, the portion having the width W1W between the drive electrode lines and the intermediate drive electrode 31DM as the other strip electrodes are adjacent to each other. Thereby, the case where the boundary line between the end drive electrode 31DE and the intermediate drive electrode is recognized is suppressed.

(8) In the end sensing electrode 33SE, the interval including the sensing electrode lines 33L adjacent to each other is the portion of the sensing electrode line width W3W Minute. Therefore, the case where the end sensing electrode 33SE and the intermediate sensing electrode 33SM are recognized as mutually different electrodes is suppressed.

In addition, the portion having the width between the sensing electrode lines W3W and the intermediate sensing electrode 33SM as the other strip electrodes are adjacent to each other as an example of the first electrode portion included in the end sensing electrode 33SE. Thereby, the case where the boundary line between the end sensing electrode 33SE and the intermediate sensing electrode 33SM is recognized is suppressed.

(9) Interference with respect to the voltage amplitude between the drive electrode lines 31L adjacent to each other is suppressed, and interference with respect to the voltage amplitude between the sensing electrode lines 33L adjacent to each other is suppressed. Therefore, the detection accuracy of the electrostatic capacitance at the end drive electrode 31DE and the end sensing electrode 33SE is further suppressed, and the detection accuracy of the electrostatic capacitance of the intermediate drive electrode 31DM or the intermediate sense electrode 33SM is lower than that.

Further, the electrostatic capacitance between the electrode lines (the drive electrode lines 31L and the sensing electrode lines 33L) in the end strip electrodes (the end drive electrodes 31DE and the end sense electrodes 33SE) is suppressed, and the transparency is made transparent. The case where the electrostatic capacitance of the dielectric substrate is large. Therefore, the detection accuracy of the electrostatic capacitance at the end strip electrode is further suppressed, and the detection accuracy of the strip electrode is lower than that of the other strip electrodes.

Further, the first embodiment described above can be implemented by being modified as follows.

‧ As shown in Fig. 8, the interval between the drive electrode lines 31L adjacent to each other across the end drive electrodes 31DE may be the width W1N between the end drive electrode lines smaller than the width W1W between the drive electrode lines.

Further, in the end sensing electrode 33SE, in the same manner, all of the sensing electrode lines 33L included in the end sensing electrodes 33SE may be spaced apart from each other by the sensing electrode lines 33L. The end portion having a small width W3W senses the width W3N between the electrode lines.

The width of the drive electrode line 31L in the end drive electrode 31DE may be the same as the width of the drive electrode line 31L in the intermediate drive electrode 31DM. In this case, the width W1N between the end drive electrode lines may be smaller than the width W1W between the drive electrode lines.

‧ As shown in Fig. 9, the end drive electrode line width W1N is set to be the same as the drive electrode line width W1W, and the drive electrode line 31L is set as the first drive electrode line. Then, the end drive electrode 31DE includes a first drive electrode line having a smaller number of strips than the intermediate drive electrode 31DM, and on the other hand, a second electrode line may be further included in addition to the first drive electrode line of one of the first electrode lines. A second driving electrode line 35L of one example. At this time, it is preferable that the second drive electrode line 35L is formed along a direction crossing the first drive electrode line, and the end drive electrode 31DE includes a drive electrode line formed in a lattice shape.

Even in such a configuration, the area of the unit area of the drive electrode line in the end drive electrode 31DE can be made larger than the area of the drive electrode line per unit area in the intermediate drive electrode 31DM. Moreover, since the interval of the first driving electrode lines adjacent to each other is maintained at the driving surface 31S, the case where the density distribution of the first driving electrode lines is recognized is suppressed. In this case, the unit area refers to a size including two or more first driving electrode lines and one or more second driving electrode lines. Moreover, even in the configuration including the second driving electrode line 35L, the above-described embodiment In the same state, the width W1N between the end driving electrode lines can still be smaller than the width W1W between the driving electrode lines.

The end sensing electrode line width W3N may be set to the same extent as the sensing electrode line width W3W, and the sensing electrode line 33L may be set as the first sensing electrode line of one of the first electrode lines. Then, the end sensing electrode 33SE includes a first sensing electrode line having fewer strips than the intermediate sensing electrode 33SM, and on the other hand, in addition to the first sensing electrode line, may further include one example of the second electrode line The second sensing electrode line. Even in such a configuration, the advantage of the configuration of the end drive electrode 31DE can be obtained at the end sensing electrode 33SE.

The end drive electrode 31DE in the above embodiment may further include the second drive electrode line, and the end sense electrode 33SE in the above embodiment may further include the second sense electrode line.

‧ In the entire end drive electrode 31DE, the interval between the adjacent drive electrode lines 31L is smaller than the width W1W between the end portions of the drive electrode lines W1N, and the drive electrode 31DE may be included in the end portion Two drive electrode lines. Further, in the entire end sensing electrode 33SE, the interval between the sensing electrode lines 33L adjacent to each other is smaller than the width W3W between the sensing electrode lines, and the width between the sensing electrodes is W3N, and the end portion can be sensed at the end The measuring electrode 33SE includes the above-described second sensing electrode line.

‧ The end drive electrode 31DE may include a drive electrode line having a line width larger than the drive electrode line width W1L in the intermediate drive electrode 31DM. Even if it is such a structure, if it is an end electrode When the width WPE is smaller than the intermediate electrode width WPM, and the area in which the drive electrode line occupies a unit area is larger than the intermediate drive electrode 31DM, the advantage as described above can still be obtained. In this case, the unit area means a size including two or more drive electrode lines 31L.

Also, the end sensing electrode 33SE may include a sensing electrode line having a line width larger than the sensing electrode line width W3L in the intermediate sensing electrode 33SM. Even in such a configuration, if the end electrode width WSE is smaller than the intermediate electrode width WSM, and the area of the sensing electrode line constituting the unit area is larger than the intermediate sensing electrode 33SM, the configuration is still The advantages described above can be obtained. At this time, the unit area means a size including two or more sensing electrode lines 33L.

The number of the driving electrode lines 31L constituting the driving electrode 31DP may be two or more, and the number of the sensing electrode lines 33L constituting the sensing electrode 33SP may be two or more.

The width W1W between the drive electrode lines of the distance between the drive electrode lines 31L adjacent to each other may be different depending on the drive electrode lines 31L adjacent to each other. In short, the drive electrode line 31L occupies an area per unit area of the end drive electrode 31DE, and may be larger than the area of the unit area of the intermediate drive electrode 31DM by the drive electrode line 31L.

The magnitude of the width W3W between the sensing electrode lines of the distance between the sensing electrode lines 33L adjacent to each other may be different as each set of sensing electrode lines 33L adjacent to each other. In short, as long as it is the sensing electrode line 33L The area per unit area in the end portion sensing electrode 33SE may be larger than the area in which the sensing electrode line 33L occupies a unit area in the intermediate sensing electrode 33SM.

‧ The target area to be sensed may be an area other than the portion overlapping the display surface 10S among the areas in which the drive electrodes 31DP are arranged. Further, the sensing target region may be a region other than the portion overlapping the display surface 10S among the regions in which the sensing electrodes 33SP are arranged. For example, the sensed object area may be an area that is inherently specified according to requirements from a configuration or manufacturing process in at least one of the touch sensor electrode 21, the touch panel 20, and the display panel 10.

‧ Only the drive electrode 31DP disposed at one end of the plurality of drive electrodes 31DP in the first arrangement direction D1 can be set as the end drive electrode 31DE. Further, only the sensing electrodes 33SP disposed at one end of the plurality of sensing electrodes 33SP in the second arrangement direction D2 may be set as the end sensing electrodes 33SE.

‧ The end drive electrode line width W1N in the end drive electrode 31DE may be the same as the drive electrode line width W1W. Alternatively, the end sensing electrode line width W3N in the end sensing electrode 33SE may be the same as the sensing electrode line width W3W. In short, the width W1N between the end driving electrode lines is smaller than the width W1W between the driving electrode lines, or the width W3N between the end sensing electrode lines is smaller than the width W3W between the sensing electrode lines.

A plurality of drive electrodes 31DP may be formed in a lattice shape by driving electrode lines that intersect each other. At this time, as long as the end driving electrode 31DE is used to make the density of the driving electrode line be made to be larger than the intermediate driving electrode The 31DM has a high density. In short, as long as the end electrode width WPE is smaller than the intermediate electrode width WPM, and the drive electrode line occupies an area per unit area in the end drive electrode 31DE, the drive electrode line occupies a larger area per unit area of the intermediate drive electrode 31DM. The composition can be.

The plurality of sensing electrodes 33SP may be formed in a lattice shape by using the sensing electrode lines that intersect each other. At this time, the end sensing electrode 33SE may have a configuration in which the density of the sensing electrode line is made higher than the density of the intermediate sensing electrode 33SM. In short, as long as the end electrode width WSE is smaller than the intermediate electrode width WSM, and the sensing electrode line occupies an area per unit area in the end sensing electrode 33SE, the sensing electrode line occupies a unit area in the intermediate sensing electrode 33SM. The large area can be configured.

‧ The end electrode width WPE may be equal to or greater than the intermediate electrode width WPM, and the end electrode width WSE may be equal to or greater than the intermediate electrode width WSM. In short, the area per unit area of the strip electrode (end strip electrode) in which the electrode line occupies the end portion in the arrangement direction may be larger than the area in which the electrode line occupies the unit area of the other strip electrode.

‧ The drive electrode 31DP is a counter strip electrode (second strip electrode), and the sense electrode 33SP may be a strip electrode (first strip electrode).

The first substrate supports a plurality of strip electrodes, and the second substrate supports a plurality of opposing strip electrodes, and the transparent dielectric substrate may comprise a first substrate and a second substrate. According to this configuration, since the capacitance of the transparent dielectric substrate is defined by the capacitance of the first substrate and the capacitance of the second substrate, the degree of freedom of the capacitance of the transparent dielectric substrate is improved.

The first substrate supports a plurality of strip electrodes, and the second substrate supports a plurality of opposing strip electrodes, and the transparent dielectric substrate may be any one of the first substrate and the second substrate. Further, the transparent dielectric substrate may be composed of one substrate. According to this configuration, since the transparent dielectric substrate is formed by any one of the first substrate and the second substrate, the thickness of the transparent dielectric substrate is prevented from being excessively thick.

[Second embodiment]

A second embodiment in which the electrode for a touch sensor, the touch panel, and the display device of the present invention are embodied will be described with reference to FIGS. 10 to 12.

Further, the main difference between the second embodiment and the first embodiment is the position of the drive electrode on the display surface, the configuration of the end drive electrode, the position of the sensing electrode on the display surface, and the configuration of the end sensing electrode. Therefore, the components that are different from the first embodiment will be mainly described below, and the same components as those in the first embodiment will be denoted by the same reference numerals, and their description will be omitted. Further, each of the tenth to twelfth drawings is a plan view showing the arrangement relationship between the display driving electrodes and the sensing electrodes, and corresponds to the fifth drawing which has been described in the first embodiment.

[Drive Electrode 31DP]

As shown in FIG. 10, one drive electrode 31DP includes nine drive line wires 31L formed in a zigzag line extending along the second arrangement direction D2, and is a strip electrode extending in the second arrangement direction D2. The respective areas of the plurality of drive electrodes 31DP are on the drive surface of the surface parallel to the display surface 10S, and include nine drive electrode lines 31L and A gap between the adjacent drive electrode lines 31L. The plurality of drive electrodes 31DP are disposed at positions overlapping with each of the plurality of sensing electrodes 33SP as viewed in plan view.

Among the plurality of drive electrodes 31DP, the drive electrodes 31DP disposed at both end portions of the region where the drive electrodes 31DP are arranged are set as the end drive electrodes 31DE. Among the plurality of drive electrodes 31DP, the drive electrodes 31DP other than the end drive electrodes 31DE are set as the intermediate drive electrodes 31DM.

In the first arrangement direction D1, the respective positions of the plurality of intermediate drive electrodes 31DM are positions overlapping the display surface 10S. The length of the plurality of intermediate drive electrodes 31DM along the first arrangement direction D1 is set to the intermediate electrode width WPM. The intermediate electrode width WPM has the same width as the pad 31T of the connection destination of the nine driving electrode lines 31L constituting the intermediate driving electrode 31DM.

In the first array direction D1, the two end drive electrodes 31DE are each located inside the region opposed to the display surface 10S. At both end drive electrodes 31DE, the length along the first arrangement direction D1 is set to the end electrode width WPE. The end electrode width WPE is the same as the width of the pad 31T of the connection destination of the nine drive electrode lines 31L constituting the end drive electrode 31DE, and is larger than the intermediate electrode width WPM.

Since the end electrode width WPE is larger than the intermediate electrode width WPM, the intermediate electrode width WPM is formed in comparison with all of the driving electrodes 31DP, and the driving electrode 31DP having the end electrode width WPE and the intermediate electrode width WPM is arranged. The length along the first arrangement direction D1 becomes longer. Therefore, the drive electrode 31DP is suppressed The end of the aligned area, in the case where an insufficient portion of the sensed object area occurs.

In the plurality of drive electrode lines 31L, the length along the first arrangement direction D1 is set to the drive electrode line width W1L, and the drive electrode line width W1L is set to, for example, 5 μm.

The drive electrode line 31L in the intermediate drive electrode 31DM has a width of the drive electrode line width W1W which is adjacent to each other, and the drive electrode line width W1W is set to, for example, 600 μm.

The drive electrode line 31L in the end drive electrode 31DE has the same width as the drive electrode line 31L in the intermediate drive electrode 31DM. That is, in each of the plurality of driving electrodes 31DP, the total area of the nine driving electrode lines 31L of each of the driving electrodes 31DP is uniform and equal to each other in the driving surface.

Further, if the total area of the drive electrode lines 31L of each of the drive electrodes 31DP is in a range in which the drive electrodes 31DP are equal to each other, the width of the drive electrode lines 31L in the end drive electrodes 31DE may be included in the intermediate drive electrodes 31DM. The drive electrode line 31L has a thick width. Further, the width of the drive electrode line 31L in the end drive electrode 31DE may include a width smaller than the drive electrode line 31L in the intermediate drive electrode 31DM.

The driving electrode line 31L in the end driving electrode 31DE, and the interval between the driving electrode lines 31L adjacent to each other are set to be the driving electrode line width W1W, and the end driving electrode line width W1N, and the end driving electrode line width. W1N is set, for example, to the width of the driving electrode line 1200 μm twice the degree of W1W. The end drive electrode 31DE includes a portion having the width W1W between the drive electrode lines as an example of the first electrode portion, and includes a portion having the width W1N between the end drive electrodes as an example of the second electrode portion.

Since the width W1N between the end driving electrode lines is larger than the width W1W between the driving electrode lines, the gap between the driving electrode lines W1W is formed in comparison with the entire gap between the driving electrode lines 31L, and the driving electrode line 31L occupies the end driving electrode. The area per unit area in the 31DE is smaller than the area per unit area of the intermediate driving electrode 31DM than the driving electrode line 31L. That is, the ratio of the total area of the driving electrode lines 31L to the area of the driving electrodes 31DP in the end driving electrodes 31DE is smaller than the ratio of the total area of the driving electrode lines 31L to the area of the intermediate driving electrodes 31DM in the intermediate driving electrodes 31DM. . At this time, the unit area in the drive electrode 31DP is a size including two or more drive electrode lines 31L in the intermediate drive electrode 31DM.

Here, the area facing the display surface 10S on the driving surface corresponds to the sensing target area requiring the function of the touch sensor. As in the case of the conventional touch sensor, when all the driving electrodes 31DP have the intermediate electrode width WPM, a gap corresponding to the difference between the intermediate electrode width WPM and the end electrode width WPE is formed at the end portion of the sensed object region, This is a portion where no drive electrode 31DP exists. Then, in order to fill such a gap, a new one of the driving electrodes 31DP is added to the end of the sensed object region, and a portion that is beyond the sensed object region is omitted.

In this regard, if the end drive electrode line width W1N is larger than the drive electrode line width W1W, it is not necessary to newly add one drive electrode 31DP, and the sensed target area is filled by the drive electrode 31DP. Then, since the total area of the drive electrode lines 31L of each of the drive electrodes 31DP is equal to each other between the drive electrodes 31DP, the electrostatic capacitance in the end drive electrodes 31DE at the ends in the first arrangement direction D1 is suppressed from becoming It is smaller than the electrostatic capacitance in the intermediate drive electrode 31DM.

Further, the two drive electrode lines 31L which are separated from each other only by the end drive electrode line width W1N are preferably located at the end of the region where the drive electrodes 31DP are arranged. The drive electrode lines 31L arranged in the width W1N between the end drive electrodes are loosely arranged than the drive electrode lines 31L arranged in the width W1W between the drive electrodes. In this regard, when the drive electrode lines 31L arranged in the width W1N between the end drive electrodes are arranged at the ends of the regions in which the drive electrodes 31DP are arranged, the loosely arranged drive electrode lines 31L become Hard to be identified.

[Sensor Electrode 33SP]

One of the sensing electrodes 33SP includes nine strip-shaped sensing electrode lines 33L formed in a line shape extending along the first array direction D1, and is a strip-shaped electrode extending in the first array direction D1. The respective areas of the plurality of sensing electrodes 33SP are included on the sensing surface of the surface parallel to the display surface 10S, and include a gap between the nine sensing electrode lines 33L and the sensing electrode lines 33L adjacent to each other. The plurality of sensing electrodes 33SP are arranged at positions overlapping with each of the plurality of driving electrodes 31DP as viewed in plan view.

Among the plurality of sensing electrodes 33SP, the sensing electrodes 33SP disposed at both end portions of the region where the sensing electrodes 33SP are arranged are set as the end sensing electrodes 33SE. Among the plurality of sensing electrodes 33SP, the sensing electrodes 33SP other than the end sensing electrodes 33SE are set as the intermediate sensing electrodes 33SM.

In the second arrangement direction D2, the respective positions of the plurality of intermediate sensing electrodes 33SM are positions overlapping the display surface 10S. The length of the plurality of intermediate sensing electrodes 33SM along the second array direction D2 is set to the intermediate electrode width WSM. The intermediate electrode width WSM has the same width as the pad 33T of the connection destination of the nine sensing electrode lines 33L constituting the intermediate driving electrode 33SM.

In the second arrangement direction D2, the two end sensing electrodes 33SE are each located inside the area facing the display surface 10S. At both end sensing electrodes 33SE, the length along the second arrangement direction D2 is set to the end electrode width WSE. The end electrode width WSE is the same as the width of the pad 33T of the connection destination of the nine sensing electrode lines 33L constituting the end sensing electrode 33SE, and is larger than the intermediate electrode width WSM.

Since the end electrode width WSE is larger than the intermediate electrode width WSM, the intermediate electrode width WSM is formed in comparison with all of the sensing electrodes 33SP, and is arranged in the sensing electrode 33SP having the end electrode width WSE and the intermediate electrode width WSM. The area is longer along the second arrangement direction D2. Therefore, it is suppressed that the end portion of the region where the sensing electrodes 33SP are arranged is insufficient for the portion to be sensed.

The length of each of the plurality of sensing electrode lines 33L along the second arrangement direction D2 is set to the sensing electrode line width W3L, and the sensing electrode line width W3L is set to, for example, 5 μm.

The sensing electrode line 33L in the intermediate sensing electrode 33SM, the interval between the sensing electrode lines 33L adjacent to each other is set to the sensing electrode line width W3W, and the sensing electrode line width W3W is set to, for example, 600 μm.

The sensing electrode line 33L in the end sensing electrode 33SE has the same width as the sensing electrode line 33L in the intermediate sensing electrode 33SM. That is, in each of the plurality of sensing electrodes 33SP, the total area occupied by the nine sensing electrode lines 33L of each of the sensing electrodes 33SP is uniform and equal to each other in the sensing surface.

Moreover, if the total area of the sensing electrode lines 33L is in a range in which the sensing electrodes 33SP are equal to each other, the width of the sensing electrode lines 33L in the end sensing electrodes 33SE may include the ratio in the intermediate sensing electrodes 33SM. The width of the electrode line 33L is sensed to be thick. Also, the width of the sensing electrode line 33L in the end sensing electrode 33SE may include a width thinner than the sensing electrode line 33L in the intermediate sensing electrode 33SM.

The sensing electrode line 33L in the end sensing electrode 33SE, the spacing of the sensing electrode lines 33L adjacent to each other is set to the sensing electrode line width W3W, and the end sensing electrode line width W3N, the end portion The sensing electrode line width W3N is, for example, set to 1200 μm which is twice the width W3W between the sensing electrode lines. The end sensing electrode 33SE includes a portion having the width W3W between the sensing electrodes as an example of the first electrode portion, and includes a portion having the width W3N between the end sensing electrodes as an example of the second electrode portion.

Since the end sensing electrode line width W3N is larger than the sensing electrode line width W3W, the entire gap between the sensing electrode lines 33L has a sensing electrode line width W3W, and the sensing electrode line 33L The area per unit area in the end sensing electrode 33SE is smaller than the area per unit area of the sensing electrode line 33L in the intermediate sensing electrode 33SM. That is, the ratio of the total area of the sensing electrode lines 33L to the area of the sensing electrodes 33SP in the end sensing electrodes 33SE is larger than the total area of the sensing electrode lines 33L in the intermediate sensing electrodes 33SM to the sensing electrodes 33SP. The ratio of the area is small. At this time, the unit area in the sensing electrode 33SP refers to a size including two or more sensing electrode lines 33L in the intermediate sensing electrode 33SM.

Here, the area facing the display surface 10S in the sensing surface corresponds to the sensing target area requiring the function of the touch sensor. As in the past touch sensor, when all of the sensing electrodes 33SP have the intermediate electrode width WSM, a gap corresponding to the difference between the intermediate electrode width WSM and the end electrode width WSE is formed at the end of the sensed object region. It is a portion where no sensing electrode 33SP exists. Then, in order to fill such a gap, a new one of the sensing electrodes 33SP is added to the end of the region where the sensing electrodes 33SP are arranged, and a portion that is beyond the sensed object region is omitted.

In this regard, if the width W3N between the end sensing electrode lines is larger than the width W3W between the sensing electrode lines, it is not necessary to newly add one sensing electrode 33SP, and the sensing target region is the sensing electrode 33SP. Landfill. Thus, since the total area of the sensing electrode lines 33L of each of the sensing electrodes 33SP is equal to each other between the sensing electrodes 33SP, the suppression is suppressed. The electrostatic capacitance in the end sensing electrode 33SE at the end portion in the second arrangement direction D2 becomes smaller than the electrostatic capacitance in the intermediate sensing electrode 33SM.

Further, the two sensing electrode lines 33L which are only separated from each other at the end sensing electrode line width W3N are preferably the end portions of the region where the sensing electrodes 33SP are arranged. The sensing electrode lines 33L arranged across the end sensing electrode line width W3N are loosely arranged than the sensing electrode lines 33L arranged across the sensing electrode line width W3W. In this regard, if the sensing electrode lines 33L arranged across the end sensing electrode line width W3N are disposed at the ends of the regions in which the sensing electrodes 33SP are arranged, the sensing electrode lines are loosely arranged. The 33L becomes difficult to recognize.

According to the second embodiment described above, in addition to the advantages of the above (1), (2), (7), and (8), the following advantages can be obtained.

(10) The end electrode width WPE of the end driving electrode 31DE is larger than the intermediate electrode width WPM, and the area of the electrode line constituting the unit area in the end driving electrode 31DE is larger than the unit area of the other driving electrode 31DP. The area is small. Therefore, a new strip electrode is added to the end portion in the arrangement direction and a part of the strip electrode is omitted, in a manner in which the strip electrode is arranged in the entire region required as the touch sensor, that is, The past configuration of the portion away from the sensed target region is removed from the drive electrode 31DP, and the end drive electrode 31DE easily obtains the same electrostatic capacitance as the other drive electrodes 31DP. That is, it is suppressed that the electrostatic capacitance of the end drive electrode 31DE becomes smaller than the electrostatic capacitance of the other drive electrode 31DP.

(11) The end electrode width WSE of the end sensing electrode 33SE is larger than the intermediate electrode width WSM, and the electrode line occupies the end portion sensing The area per unit area in the electrode 33SE is smaller than the area of the electrode line occupying the unit area in the other sensing electrodes 33SP. Therefore, a new strip electrode is added to the end portion in the arrangement direction, and the configuration of a part of the strip electrode is omitted, in contrast to the manner in which the strip electrodes are arranged in all regions required as the touch sensor. The past configuration of the portion away from the sensed target region is removed from the sensing electrode 33SP, and the end sensing electrode 33SE easily obtains the same electrostatic capacitance as the other sensing electrodes 33SP. That is, the case where the electrostatic capacitance of the end sensing electrode 33SE becomes smaller than the electrostatic capacitance of the other sensing electrodes 33SP is suppressed.

(12) The end portion of the driving electrode line 31L adjacent to each other at the end driving electrode 31DE drives the width W1N between the electrode lines, whereby the area of the electrode line constituting the unit area becomes larger than that of the other strip electrodes (ie, the middle The drive electrode 31DM) is small. Therefore, when the area of the unit line area is suppressed, it is not necessary to change the size of the drive electrode line 31L, and it is not necessary to change the shape of the drive electrode line 31L.

(13) At the end sensing electrode 33SE, the interval between the sensing electrode lines 33L adjacent to each other senses the width W3N between the electrode lines, whereby the area of the electrode line constituting the unit area becomes larger than that of the other strip electrodes ( That is, the intermediate sensing electrode 33SM) is small. Therefore, when the area of the unit area is suppressed, it is not necessary to change the size of the sensing electrode line 33L, and it is not necessary to change the shape of the sensing electrode line 33L.

Further, the second embodiment described above can be modified and implemented in the following manner.

‧ In the entire end drive electrode 31DE, the interval between the drive electrode lines 31L adjacent to each other may be the width W1N between the end drive electrode lines larger than the width W1W between the drive electrode lines.

Further, in the end sensing electrode 33SE, in the same manner, all of the sensing electrode lines 33L included in the end sensing electrodes 33SE may be spaced apart from each other by the sensing electrode lines 33L. The end portion having a large width W3W senses the width W3N between the electrode lines.

‧ As shown in the left end of Fig. 10, the dummy pattern 33DL of one example of the non-connecting line different from the driving electrode line 31L may be located at two driving electrode lines having an example of one of the connecting lines having the width W1N between the end driving electrodes Between 31L. At this time, the dummy pattern 33DL is preferably made of the same material as the driving electrode line 31L. Moreover, it is preferable that the dummy pattern 33DL is located at a position spaced apart from the pad 31T by the gap portion 31C, and has almost the same shape as the drive electrode line 31L. Further, the gap portion 31C is preferably located between the sensed object region and the pad 31T.

Further, the dummy pattern 31DL different from the sensing electrode line 33L may be located between the two sensing electrode lines 33L having the end sensing electrode line width W3N. At this time, the dummy pattern 31DL is preferably made of the same material as the sensing electrode line 33L. Further, the dummy pattern 31DL is preferably located at a position where the pad 33T of the connection destination of the sensing electrode line 33L is separated by the gap 33C, and has almost the same shape as the sensing electrode line 33L. In addition, the gap 33C is preferably located between the sensed object area and the pad 33T.

Further, as shown in FIG. 11, the dummy pattern 33DL may have a shape divided by two or more gap portions 31C, and the dummy pattern 31DL may have a shape divided by two or more gaps 33C. At this time, the two or more gap portions 31C are preferably located between the sensing electrodes 33SP adjacent to each other in plan view, and more than two or more The gap 33C is preferably located between the drive electrodes 31DP adjacent to each other in plan view.

According to the above modification, in addition to the advantages of (10) to (13) as described above, the following advantages can be obtained.

(14) The case where the end drive electrode 31DE and the intermediate drive electrode 31DM are recognized as mutually different strip electrodes is also suppressed.

(15) The case where the end sensing electrode 33SE and the intermediate sensing electrode 33SM are recognized as mutually different strip electrodes is also suppressed.

(16) The drive electrode line 31L and the dummy pattern 33DL have almost the same shape. Thus, for example, ten driving electrode lines 31L connected to one pad 31T may be formed, and one of the ten driving electrode lines 31L may be cut by the gap portion 31C, thereby forming the dummy pattern 33DL. Moreover, it is easier to make the dummy pattern 33DL located in a gap having a width W1N between the end drive electrode lines having a width wider than the width W1W between the drive electrode lines.

(17) The sensing electrode line 33L and the dummy pattern 31DL have almost the same shape. Thus, for example, ten sensing electrode lines 33L connected to one pad 33T may be formed, and one of the ten sensing electrode lines 33L may be cut by the gap 33C, thereby forming the dummy pattern 31DL. Moreover, it is easier to make the dummy pattern 31DL located in a gap having a width W3N between the end sensing electrode lines having a width wider than the width W3W between the sensing electrode lines.

(18) Since the gap portion 31C or the gap 33C is located outside the sensed target region, the case where the drive electrode line 31L and the dummy pattern 33DL are recognized as mutually different electrode lines is suppressed, and the sense electrode line 33L is suppressed. And the case where the dummy pattern 31DL is recognized as mutually different electrode lines.

(19) If the gap portion 31C is located between the sensing electrodes 33SP adjacent to each other, the floating capacitance of the dummy pattern 33DL becomes equal to each of the sensing electrodes 33SP. Therefore, even if the configuration of the dummy pattern 33DL having the floating capacitance is added, the case where the electrostatic capacitance between each of the plurality of sensing electrodes 33SP and the end driving electrode 31DE is different depending on the sensing electrode 33SP is suppressed.

The end drive electrode 31DE may include a drive electrode line having a line width larger than the drive electrode line width W1L in the intermediate drive electrode 31DM. Even in such a configuration, if the total area of the drive electrode lines 31L is equal to each drive electrode 31DP, and the ratio of the total area of the drive electrode lines 31L to the area of the drive electrodes 31DP in the end drive electrodes 31DE is If the ratio of the intermediate drive electrodes 31DM is small, the advantages as described above can be obtained.

Also, the end sensing electrode 33SE may include a sensing electrode line having a line width larger than the sensing electrode line width W3L in the intermediate sensing electrode 33SM. Even in such a configuration, if the total area of the sensing electrode lines 33L is equal to each of the sensing electrodes 33SP, and the total area of the sensing electrode lines 33L is opposite to the area of the sensing electrodes 33SP in the end sensing electrodes 33SE When the ratio is smaller than the ratio in the intermediate sensing electrode 33SM, the above-described effects can be obtained.

The number of the driving electrode lines 31L constituting the driving electrode 31DP may be two or more, and the number of the sensing electrode lines 33L constituting the sensing electrode 33SP may be two or more.

The width W1W between the drive electrode lines of the distance between the drive electrode lines 31L adjacent to each other may be different depending on the drive electrode lines 31L adjacent to each other.

Further, the magnitude of the inter-sensor line width W3W of the distance between the sensing electrode lines 33L adjacent to each other may be different as each set of sensing electrode lines 33L adjacent to each other.

A plurality of drive electrodes 31DP may be formed in a lattice shape by driving electrode lines that intersect each other. In this case, the end drive electrode 31DE may have a configuration in which the density of the drive electrode line is lower than the density of the intermediate drive electrode 31DM.

Further, the plurality of sensing electrodes 33SP may be formed in a lattice shape by using the sensing electrode lines that intersect each other. At this time, the end sensing electrode 33SE may have a configuration in which the density of the sensing electrode line is made lower than the density of the intermediate sensing electrode 33SM.

‧ The end electrode width WPE may be equal to or greater than the intermediate electrode width WPM, and the end electrode width WSE may be equal to or greater than the intermediate electrode width WSM.

In short, if the total area of the driving electrode lines 31L is equal to each driving electrode 31DP, and the ratio of the total area of the driving electrode lines 31L to the area of the driving electrodes 31DP in the end driving electrodes 31DE is larger than that in the intermediate driving electrodes 31DM The composition is smaller than that.

Moreover, if the total area of the sensing electrode lines 33L is equal to each sensing electrode 33SP, and the ratio of the total area of the sensing electrode lines 33L to the area of the sensing electrodes 33SP in the end sensing electrodes 33SE is The above-described ratio of the intermediate sensing electrodes 33SM may be small.

‧ Only the drive electrode 31DP disposed at one end of the plurality of drive electrodes 31DP in the first arrangement direction D1 can be set as the end drive electrode 31DE. Also, it is also possible to use only a plurality of sensing electrodes Among the poles 33SP, the sensing electrodes 33SP disposed at one end portion in the second array direction D2 are set as the end sensing electrodes 33SE.

‧ The end drive electrode line width W1N in the end drive electrode 31DE may be the same as the drive electrode line width W1W. Alternatively, the end sensing electrode line width W3N in the end sensing electrode 33SE may be the same as the sensing electrode line width W3W. In short, the end drive electrode line width W1N may be larger than the drive electrode line width W1W, or the end sense electrode line width W3N may be larger than the sense electrode line width W3W.

In the above embodiments, the back surface of the cover layer 22 may be set on the sensing surface, and the back surface of the cover layer 22 may have the sensing electrode 33SP. Further, the back surface of the transparent dielectric substrate 33 may be set as the driving surface 31S, and the back surface of the transparent dielectric substrate 33 may have the driving electrode 31DP. At this time, the transparent substrate 31 can be omitted.

As shown in FIG. 13, in the touch sensor electrode 21 constituting the touch panel 20, the transparent substrate 31 can be omitted. In such a configuration, one surface of the surface of the transparent dielectric substrate 33 that faces the display panel 10 is set as the driving surface 31S, and the driving electrode 31DP is located on the driving surface 31S. Therefore, the sensing electrode 33SP may be located on the surface of the transparent dielectric substrate 33 that faces the driving surface 31S. Further, in such a configuration, the pad 31T or the electrode wire 31L constituting the drive electrode 31DP is formed, for example, by patterning one thin film formed on the drive surface 31S.

‧ As shown in FIG. 14 , in the touch panel 20 , the driving electrodes can be sequentially placed from the components close to the display panel 10 . 31DP, transparent substrate 31, transparent adhesive layer 32, transparent dielectric substrate 33, sensing electrode 33SP, transparent adhesive layer 23, and cover layer 22. In addition, for example, the pad 31T or the electrode line 31L constituting the drive electrode 31DP is formed on the drive surface 31S of one surface of the transparent substrate 31, and the pad 33T or the electrode line 33L constituting the sensing electrode 33SP is formed in a transparent manner. The sensing surface 33S of one surface of the dielectric substrate 33 is such that the surface of the transparent substrate 31 facing the driving surface 31S and the surface corresponding to the sensing surface 33S in the transparent dielectric substrate 33 are transparent. Layer 32 is then followed.

The touch panel 20 and the display panel 10 may not be formed separately, and the touch panel 20 may be integrally formed with the display panel 10. In such a configuration, for example, among the touch sensor electrodes 21, a plurality of drive electrodes 31DP are located on the TFT layer 13, and on the other hand, a plurality of sensing electrodes 33SP are located on the color filter substrate 16 and Between the upper polarizing plates 17. Alternatively, the touch sensor electrode 21 may be disposed between the color filter substrate 16 and the upper polarizing plate 17.

D1‧‧‧Arrangement direction, first alignment direction

D2‧‧‧Second alignment direction

WPM‧‧‧Intermediate electrode width

WPE‧‧‧End electrode width

W1L‧‧‧Drive electrode line width

W1W‧‧‧ drive electrode line width

W1N‧‧‧End drive electrode line width

10S‧‧‧ display surface

31DP‧‧‧Strip electrode, drive electrode

31L‧‧‧electrode wire

31L‧‧‧ drive electrode line

31T‧‧‧ pads

31DE‧‧‧End Drive Electrode

31DM‧‧‧Intermediate drive electrode

Claims (15)

An electrode for a touch sensor includes a plurality of strip electrodes arranged at a constant interval along a direction in which the one direction is arranged, and each of the strip electrodes is a set of a plurality of electrode lines arranged at intervals The total area of the plurality of electrode lines of each of the strip electrodes is uniform among a plurality of the strip electrodes, and the plurality of strip electrodes include: end strips of at least one end portion in the arrangement direction a strip electrode and a strip electrode other than the end strip electrode; wherein each of the strip electrodes has a ratio of a total area of the electrode lines to an area of the strip electrodes as an area ratio, and the end portion The aforementioned area ratio in the strip electrode is different from the aforementioned area ratio in the other strip electrodes described above. The electrode for touch sensor of claim 1, wherein the aforementioned area ratio in the end strip electrode is larger than the aforementioned area ratio in the other strip electrodes. The electrode for touch sensor of claim 1, wherein the aforementioned area ratio in the end strip electrode is smaller than the aforementioned area ratio in the other strip electrodes. The electrode for a touch sensor of claim 1, wherein the end strip electrode comprises a first electrode portion, the electrode line occupies an area per unit area of the first electrode portion, and the electrode line occupies the other band Unit surface in the electrode The area of the product is equal, and the interval between the electrode lines adjacent to each other in the first electrode portion is equal to the interval between the electrode lines adjacent to each other among the other strip electrodes. The electrode for a touch sensor of claim 4, wherein the end strip electrode further comprises a second electrode portion, wherein the electrode line occupies an area per unit area of the second electrode portion, and the electrode line occupies the other The area of the unit area in the strip electrode is large, and the interval between the electrode lines adjacent to each other in the second electrode portion is narrower than the interval between the electrode lines adjacent to each other among the other strip electrodes. The electrode for a touch sensor of claim 4, wherein the end strip electrode further comprises a second electrode portion, wherein the electrode line occupies an area per unit area of the second electrode portion, and the electrode line occupies the other The area of the unit area in the strip electrode is small, and the interval between the electrode lines adjacent to each other in the second electrode portion is wider than the interval between the electrode lines adjacent to each other among the other strip electrodes. The electrode for touch sensor of claim 5 or 6, wherein the first electrode portion of the end strip electrode is located between the second electrode portion and the other strip electrode. The electrode for a touch sensor according to claim 6, wherein each of the strip electrodes further includes a pad connected to the electrode line, and the second electrode portion includes a connection line connected to the electrode line of the pad; The non-connecting wire is not connected to the pad, and the end strip electrode has an electrode portion which is spaced apart from each other by an electrode line which is spaced apart from the other electrode wires adjacent to each other among the other strip electrodes The interval is wide, and the non-connection line is located at the electrode portion of the end strip electrode. The electrode for a touch sensor of claim 2, further comprising a transparent dielectric substrate, the transparent dielectric substrate having: a surface of the plurality of first strip electrodes arranged along the first direction, and a plurality of The second strip electrode is arranged on the back surface arranged in the second direction different from the first direction, and at least one of the first strip electrode and the second strip electrode is the strip electrode, and the end strip electrode is The interval between the electrode lines adjacent to each other is twice or more the interval between the surface and the back surface. The electrode for touch sensor of claim 2, wherein all of the strip electrodes each comprise a first electrode line constituting the electrode line, and the other strip electrodes are formed by the first electrode line, the end band The electrode includes a second electrode line other than the aforementioned first electrode line. A touch panel, comprising: an electrode for a touch sensor according to any one of claims 1 to 10; and a cover layer covering the electrode for the touch sensor, wherein the electrode for the touch sensor is transparent: Dielectric substrate; a plurality of first strip electrodes arranged in a gap along a first direction in a surface of the transparent dielectric substrate; and a plurality of second strip electrodes on a back surface of the transparent dielectric substrate And arranging at least one of the first strip electrode and the second strip electrode as the strip electrode in the second direction, and further comprising: a peripheral circuit for measuring the first strip electrode and the first The electrostatic capacitance between the two strip electrodes. The touch panel of claim 11, comprising: a first substrate supporting the plurality of first strip electrodes; and a second substrate supporting the plurality of second strip electrodes, the transparent dielectric The substrate comprises the aforementioned first substrate and the aforementioned second substrate. The touch panel of claim 11, comprising: a first substrate supporting the plurality of first strip electrodes; and a second substrate supporting the plurality of second strip electrodes, the transparent dielectric The substrate is any one of the first substrate and the second substrate. The touch panel of claim 11, wherein the transparent dielectric substrate is composed of one substrate. A display device comprising: a display panel for displaying information; a driving circuit for driving the display panel; and the touch panel of any one of claims 11 to 14 for transmitting the information displayed by the display panel.